A novel rho promoter::Tn10 mutation suppresses and ftsQ1(Ts) missense mutation in an essential Escherichia coli cell division gene by a mechanism not involving polarity suppression

Mastering the control of the Rho transcription factor for biotechnological applications

The present review represents an update on the fundamental role played by the Rho factor, which facilitates the process of Rho-dependent transcription termination in the prokaryotic world; it also provides a summary of relevant mutations in the Rho factor and the insights they provide into the functions carried out by this protein. Furthermore, a section is dedicated to the putative future use of Rho (the 'taming' of Rho) to facilitate biotechnological processes and adapt them to different technological contexts. Novel bacterial strains can be designed, containing mutations in the rho gene, that are better suited for different biotechnological applications. This process can obtain novel microbial strains that are adapted to lower temperatures of fermentation, shorter production times, exhibit better nutrient utilization, or display other traits that are beneficial in productive Biotechnology. Additional important issues reviewed here include epistasis, the design of TATA boxes, the role of small RNAs, and the manipulation of clathrin-mediated endocytosis, by some pathogenic bacteria, to invade eukaryotic cells. KEY POINTS: • It is postulated that controlling the action of the prokaryotic Rho factor could generate major biotechnological improvements, such as an increase in bacterial productivity or a reduction of the microbial-specific growth rate. • The review also evaluates the putative impact of epistatic mechanisms on Biotechnology, both as possible responsible for unexpected failures in gene cloning and more important for the genesis of new strains for biotechnological applications • The use of clathrin-coated vesicles by intracellular bacterial microorganisms is included too and proposed as a putative delivery mechanism, for drugs and vaccines.

The β-lactam resistance protein Blr, a small membrane polypeptide, is a component of the Escherichia coli cell division machinery

In Escherichia coli, cell division is performed by a multimolecular machinery called the divisome, made of 10 essential proteins and more than 20 accessory proteins. Through a bacterial two-hybrid library screen, we identified the E. coli β-lactam resistance protein Blr, a short membrane polypeptide of 41 residues, as an interacting partner of the essential cell division protein FtsL. In addition to FtsL, Blr was found to associate with several other divisomal proteins, including FtsI, FtsK, FtsN, FtsQ, FtsW, and YmgF. Using fluorescently tagged Blr, we showed that this peptide localizes to the division septum and that its colocalization requires the presence of the late division protein FtsN. Although Blr is not essential, previous studies have shown that the inactivation of the blr gene increased the sensitivity of bacteria to β-lactam antibiotics or their resistance to cell envelope stress. Here, we found that Blr, when overproduced, restores the viability of E. coli ftsQ1(Ts) cells, carrying a thermosensitive allele of the ftsQ gene, during growth under low-osmotic-strength conditions (e.g., in synthetic media or in Luria-Bertani broth without NaCl). In contrast, the inactivation of blr increases the osmosensitivity of ftsQ1(Ts) cells, and blr ftsQ1 double mutants exhibit filamentous growth in LB broth even at a moderate salt concentration (0.5% NaCl) compared to parental ftsQ1(Ts) cells. Altogether, our results suggest that the small membrane polypeptide Blr is a novel component of the E. coli cell division apparatus involved in the stabilization of the divisome under certain stress conditions.

The essential peptidoglycan glycosyltransferase MurG forms a complex with proteins involved in lateral envelope growth as well as with proteins involved in cell division in Escherichia coli

In Escherichia coli many enzymes including MurG are directly involved in the synthesis and assembly of peptidoglycan. MurG is an essential glycosyltransferase catalysing the last intracellular step of peptidoglycan synthesis. To elucidate its role during elongation and division events, localization of MurG using immunofluorescence microscopy was performed. MurG exhibited a random distribution in the cell envelope with a relatively higher intensity at the division site. This mid-cell localization was dependent on the presence of a mature divisome. Its localization in the lateral cell wall appeared to require the presence of MreCD. This could be indicative of a potential interaction between MurG and other proteins. Investigating this by immunoprecipitation revealed the association of MurG with MreB and MraY in the same protein complex. In view of this, the loss of rod shape of ΔmreBCD strain could be ascribed to the loss of MurG membrane localization. Consequently, this could prevent the localized supply of the lipid II precursor to the peptidoglycan synthesizing machinery involved in cell elongation. It is postulated that the involvement of MurG in the peptidoglycan synthesis concurs with two complexes, one implicated in cell elongation and the other in division. A model representing the first complex is proposed.

A new in vivo termination function for DNA polymerase I of Escherichia coli K12

Escherichia coli deleted for the tus gene are viable. Thus there must be at least one other mechanism for terminating chromosome synthesis. The tus deletion strain yielded a small fraction of cells that overproduce DNA, as determined by flow cytometry after run-out chromosome replication in the presence of rifampicin and cephalexin. A plasmid, paraBAD tus+, prevented the excess DNA replication only when arabinose was added to the medium to induce the synthesis of the Tus protein. Transduction studies were done to test whether or not additional chromosomal deletions could enhance the excess chromosome replication in the tus deletion strain. A strain containing a second deletion in metE udp overproduced DNA at a high level during run-out replication. Further studies demonstrated that a spontaneous unknown mutation had occurred during the transduction. This mutation was mapped and sequenced. It is polA(G544D). Transduction of polA(G544D) alone into the tus deletion strain produced the high DNA overproduction phenotype. The polA(G544D) and six other polA alleles were then tested in wild-type and in tus deletion backgrounds. The two alleles with low levels of 5'-->3' exonuclease (exo) overproduced DNA while those with either high or normal exo overproduce much less DNA in run-out assays in the wild-type background. In contrast, all seven mutant polA alleles caused the high DNA overproduction phenotype in a tus deletion background. To explain these results we propose a new in vivo function for wild-type DNA polymerase I in chromosome termination at site(s) not yet identified.

Maturation of the Escherichia coli divisome occurs in two steps

Cell division proteins FtsZ (FtsA, ZipA, ZapA), FtsE/X, FtsK, FtsQ, FtsL/B, FtsW, PBP3, FtsN and AmiC localize at mid cell in Escherichia coli in an interdependent order as listed. To investigate whether this reflects a time dependent maturation of the divisome, the average cell age at which FtsZ, FtsQ, FtsW, PBP3 and FtsN arrive at their destination was determined by immuno- and GFP-fluorescence microscopy of steady state grown cells at a variety of growth rates. Consistently, a time delay of 14-21 min, depending on the growth rate, between Z-ring formation and the mid cell recruitment of proteins down stream of FtsK was found. We suggest a two-step model for bacterial division in which the Z-ring is involved in the switch from cylindrical to polar peptidoglycan synthesis, whereas the much later localizing cell division proteins are responsible for the modification of the envelope shape into that of two new poles.

Analysis of ftsQ mutant alleles in Escherichia coli: complementation, septal localization, and recruitment of downstream cell division proteins

FtsQ, a 276-amino-acid, bitopic membrane protein, is one of the nine proteins known to be essential for cell division in gram-negative bacterium Escherichia coli. To define residues in FtsQ critical for function, we performed random mutagenesis on the ftsQ gene and identified four alleles (ftsQ2, ftsQ6, ftsQ15, and ftsQ65) that fail to complement the ftsQ1(Ts) mutation at the restrictive temperature. Two of the mutant proteins, FtsQ6 and FtsQ15, are functional at lower temperatures but are unable to localize to the division site unless wild-type FtsQ is depleted, suggesting that they compete poorly with the wild-type protein for septal targeting. The other two mutants, FtsQ2 and FtsQ65, are nonfunctional at all temperatures tested and have dominant-negative effects when expressed in an ftsQ1(Ts) strain at the permissive temperature. FtsQ2 and FtsQ65 localize to the division site in the presence or absence of endogenous FtsQ, but they cannot recruit downstream cell division proteins, such as FtsL, to the septum. These results suggest that FtsQ2 and FtsQ65 compete efficiently for septal targeting but fail to promote the further assembly of the cell division machinery. Thus, we have separated the localization ability of FtsQ from its other functions, including recruitment of downstream cell division proteins, and are beginning to define regions of the protein responsible for these distinct capabilities.

Localization of cell division protein FtsQ by immunofluorescence microscopy in dividing and nondividing cells of Escherichia coli

The localization of cell division protein FtsQ in Escherichia coli wild-type cells was studied by immunofluorescence microscopy with specific monoclonal antibodies. FtsQ could be localized to the division site in constricting cells. FtsQ could also localize to the division site in ftsQ1(Ts) cells grown at the permissive temperature. A hybrid protein in which the cytoplasmic domain and the transmembrane domain were derived from the gamma form of penicillin-binding protein 1B and the periplasmic domain was derived from FtsQ was also able to localize to the division site. This result indicates that the periplasmic domain of FtsQ determines the localization of FtsQ, as has also been concluded by others for the periplasmic domain of FtsN. Noncentral FtsQ foci were found in the area of the cell where the nucleoid resides and were therefore assumed to represent sites where the FtsQ protein is synthesized and simultaneously inserted into the cytoplasmic membrane.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

An Escherichia coli gene (yaeO) suppresses temperature-sensitive mutations in essential genes by modulating Rho-dependent transcription termination

An extragenic multicopy suppressor of the cell division inhibition caused by a MalE-MinE fusion protein in Escherichia coli has been mapped and identified as yaeO, one of the two short open reading frames (ORFs) of an operon located at 4.6 min. Overexpressed yaeO also suppressed some temperature-sensitive mutations in division genes ftsA and ftsQ, in chaperone gene groEL and in co-chaperone gene grpE. Gene yaeO, whose expression is regulated by growth rate, codes for a 9 kDa acidic protein with no obvious resemblance to other proteins. Transcription termination protein Rho co-purified with a histidine-tagged derivative of YaeO protein on Ni2+-NTA agarose columns in a manner that suggested direct YaeO-Rho interaction. In vivo, yaeO expression reduced termination at rho-dependent bacteriophage terminator tL1 and at the terminator of autogenously regulated gene rho. The suppression of temperature-sensitive phenotypes was a consequence of anti-termination, as it could be mimicked by a Prho::Tn10 mutation that reduces the expression and activity of gene rho. Our data indicate that the suppression is not caused by overexpression of the mutated genes, but presumably by indirect stabilization of the mutated proteins.

Cell division gene ftsQ is required for efficient sporulation but not growth and viability in Streptomyces coelicolor A3(2)

We show that the cell division gene ftsQ of Streptomyces coelicolor A3(2) is dispensable for growth and viability but is needed during development for the efficient conversion of aerial filaments into spores. Combined with our previous demonstration that ftsZ of S. coelicolor is not needed for viability, these findings suggest that cell division has been largely co-opted for development in this filamentous bacterium. This makes S. coelicolor an advantageous system for the study of cell division genes.

Deregulation of temperature-dependent transcription of the invasion regulatory gene, virB, in Shigella by rho mutation

Expression of the virB gene, the transcriptional regulator for the invasion genes encoded by the large plasmid of Shigella flexneri, is temperature-regulated. virB transcription is under the control of VirF and H-NS, which act as positive and negative regulators, respectively, and is highly responsive to changes in DNA superhelicity. To further investigate the molecular mechanisms underlying the thermoregulation of virB transcription, a mutant which expressed an invasion phenotype at both 30 degrees C and 37 degrees C was isolated using miniTn10-kan (miniKAN) random insertion mutagenesis. The insertion site was mapped to the rho gene, and resulted in the addition of 11 amino acids to the C-terminus of the Rho protein. Consequently, decreased transcription termination activity at a rho-dependent terminator, lambda tL1, was observed. In the rho mutant, both the transcription of virB and expression of invasion genes were activated at 30 degrees C and were less responsive to changes in temperature. The deregulation of virB expression by the mutation was dependent upon the virB promoter, since the effects of the mutation on virB transcription were abolished when its promoter region was replaced by the tac promoter. Temperature-responsive changes in DNA topology, as determined by linking numbers of a reporter plasmid, showed that changes in DNA superhelicity in the rho mutant were smaller than that in the wild type. Furthermore, when the mutant was grown in medium containing novobiocin, an inhibitor of DNA gyrase, virB transcription at 30 degrees C as well as at 37 degrees C was greatly diminished. These results indicated that Rho protein could have a profound effect on topological temperature-dependent changes in DNA structure, thus contributing to thermoregulation of virB transcription.

Identification of a Salmonella typhimurium invasion locus by selection for hyperinvasive mutants

Salmonella typhimurium penetrate intestinal epithelial cells during infection. In vitro studies reveal that the availability of oxygen during bacterial growth decreases their capacity to adhere to and enter cultured epithelial cells. To identify S. typhimurium genes involved in epithelial cell entry, mutants were selected that entered HEp-2 cells when grown under repressing, aerobic culture conditions. Two types of transposons were used to generate bacterial mutations--transposons that disrupt genes (Tn10 and Tn5) and one transposon (Tn5B50) that, in addition to disrupting genes, can cause constitutive expression of genes from the neo promoter at one end of the transposon. Three classes of mutations were found that increased the ability of aerobically grown S. typhimurium to enter HEp-2 cells. One class of mutations disrupts the che operons and results in a nonchemotactic phenotype. The second class of mutations revealed that defects in rho, which encodes an essential transcription termination factor, result in hyperinvasiveness. The third class of mutations was obtained only from mutagenesis with Tn5B50, suggesting that their increased invasiveness is due to constitutive expression of a gene(s) from the exogenous neo promoter. Analysis of this third class of mutations identified a S. typhimurium locus hil (hyperinvasion locus), which is essential for bacterial entry into epithelial cells. The results suggest that hil encodes an invasion factor or an activator of invasion factor expression. hil maps between srl and mutS near minute 59.5 of the S. typhimurium chromosome, a region adjacent to other loci that have been identified as required for S. typhimurium invasiveness and virulence.